Isolation of Aspergillus nidulans Mutants That Overcome brlA-Induced Growth Arrest

The Aspergillus nidulans brlA gene is a primary regulator of development-specific gene expression during conidiation. Forced activation of brlA in vegetative cells leads to inappropriate induction of conidiophore formation and causes growth to stop. In fact, when conidia containing a nutritionally inducible brlA gene fusion are placed on inducing medium, they fail to germinate. We used this phenotype to select 174 mutants that continue growing following such forced brlA activation. Forty-six of these mutants also produced abnormal developmental structures during air-induced conidiation as expected if the mutations resulted in an altered response to BrlA (designated sbr mutants for suppressors of brlA response). The predominant mutant class identified was defective in a known developmental regulatory gene, abaA. We also identified mutants with defects in the previously characterized early acting developmental regulatory genes flbB and flbD and in four previously undescribed loci designated sbrA-D. sbrA mutants represent the second largest group and are characterized by production of conidiophore stalks that lack a normal vesicle and form branching sterigmata that rarely make spores. Because abaA expression could not be detected in sbrA mutants following brlA activation we propose that sbrA functions as a developmental modifier, participating in brlA-dependent activation of other developmental regulators.     

Association of ergot alkaloids with conidiation in Aspergillus fumigatus

Ergot alkaloids are mycotoxins that affect the nervous and reproductive systems of exposed individuals through interactions with monoamine receptors. They have been studied more widely in ergot fungi and grass endophytes but also are found in Aspergillus fumigatus, an opportunistic human pathogen that reproduces and disseminates exclusively through conidia. The ergot alkaloids festucla-vine and fumigaclavines A, B and C are present in or on conidia of A. fumigatus. Cultures of the fungus that are free of conidia are difficult to obtain, obscuring comparisons of conidia versus vegetative hyphae as sources of the ergot alkaloids. To create conidiation-deficient strains of A. fumigatus we manipulated the bristle A gene (brlA), which controls vesicle formation or budding growth necessary for conidiation in Aspergillus spp. Disruption of brlA in A. fumigatus, via homologous recombination, resulted in a nonconidiating mutant that produced bristle-like structures instead of conidiophores and conidia. Moreover the disrupted strain failed to produce ergot alkaloids as verified by HPLC analyses. Complementation with a wild-type allele restored conidiation and ergot alkaloid production. These results suggest that ergot alkaloids are not produced within the vegetative mycelium of the fungus and are associated directly with conidiation.     

TmpA, a member of a novel family of putative membrane flavoproteins, regulates asexual development in Aspergillus nidulans

Asexual reproduction (conidiation) in Aspergillus nidulans is induced by environmental signals like exposure to air or nutrient starvation, and depends on brlA gene activation. The study of 'fluffy' mutants showing delayed asexual development and reduced brlA expression has defined the fluG pathway, involved in regulation of this differentiation process. Genetic characterization of a 'fluffy' mutant identified tmpA as a new gene involved in regulation of conidiation. TmpA defines a new family of putative transmembrane proteins of unknown function, widespread in filamentous fungi and plants, with homologues showing similarity to non-ribosomal peptide synthetases. The deletion of tmpA resulted in decreased brlA expression and conidiation in air-exposed colonies. This defect was suppressed when DeltatmpA mutants were grown next to wild-type or DeltafluG mutant colonies, even without direct contact between hyphae. In liquid culture, tmpA was essential for conidiation induced by nitrogen but not by carbon starvation, whereas the overexpression of different tmpA tagged alleles resulted in conidiation. The overexpression of fluG-induced conidiation independently of tmpA and DeltatmpADeltafluG double mutants showed an additive 'fluffy' phenotype, indicating that tmpA and fluG regulate asexual sporulation through different pathways. TmpA and its homologues appear to have diverged from the ferric reductase family, retaining overall transmembrane architecture, NAD(P), flavin adenine dinucleotide (FAD) and possibly haem-binding domains. Based on our results, we propose that TmpA is a membrane oxidoreductase involved in the synthesis of a developmental signal.     

Interactions of three sequentially expressed genes control temporal and spatial specificity in Aspergillus development

Aspergillus nidulans brlA, abaA, and wetA form a dependent pathway that regulates asexual reproductive development. The order in which these genes are expressed determines the outcome of development. Expression of brlA in vegetative cells leads to activation of abaA and wetA, cessation of vegetative growth, cellular vacuolization, and spore formation. By contrast, expression of abaA in vegetative cells does not result in conidial differentiation but does lead to activation of brlA and wetA, cessation of vegetative growth, and accentuated cellular vacuolization. brlA, abaA, and wetA act individually and together to regulate their own expression and that of numerous other sporulation-specific genes. We propose that the central pathway controlling development is largely autoregulatory. The timing and extent of expression of the regulatory genes and their targets are determined as development proceeds by intrinsically controlled changes in the relative concentrations of regulatory gene products in the various conidiophore cell types.     

Heterotrimeric Galpha protein Pga1 of Penicillium chrysogenum controls conidiation mainly by a cAMP-independent mechanism.

Fungal heterotrimeric G proteins regulate different processes related to development, such as colony growth and asexual sporulation, the main mechanism of propagation in filamentous fungi. To gain insight into the mechanisms controlling growth and differentiation in the industrial penicillin producer Penicillioum chrysogenum, we investigated the role of the heterotrimeric Galpha subunit Pga1 in conidiogenesis. A pga1 deleted strain (Deltapga1) and transformants with constitutively activated (pga1G42R) and inactivated (pga1G203R) Pga1 alpha subunits were obtained. They showed phenotypes that clearly implicate Pga1 as an important negative regulator of conidiogenesis. Pga1 positively affected the level of intracellular cAMP, which acts as secondary messenger of Pga1-mediated signalling. Although cAMP has some inhibitory effect on conidiation, the regulation of asexual development by Pga1 is exerted mainly via cAMP-independent pathways. The regulation of conidiation by Pga1 is mediated by repression of the brlA and wetA genes. The Deltapga1 strain and transformants with the constitutively inactive Pga1G203R subunit developed a sporulation microcycle in submerged cultures triggered by the expression of brlA and wetA genes, which are deregulated in the absence of active Pga1. Our results indicate that although basic mechanisms for regulating conidiation are similar in most filamentous fungi, there are differences in the degree of involvement of specific pathways, such as the cAMP-mediated pathway, in the regulation of this process.     

The genetics of conidiophore pigmentation in Aspergillus nidulans

The grey-brown pigmentation of Aspergillus nidulans conidiophores depends on the functions of two 'ivory' loci. ivoB codes for a developmental specific phenol oxidase, and mutants accumulate its substrate N-acetyl-6-hydroxytryptophan. ivoA mutants are unable to make this substrate. ygA mutants are also poorly pigmented, and extracts require copper salts to activate both the phenol oxidase and conidial laccase. ivoA and ivoB mutants partially suppress the spore colour phenotype of ygA mutants. Comparisons of morphology, phenol oxidase and substrate accumulation in morphological mutants at the brlA locus suggest that the brlA protein regulates ivoA, ivoB and morphogenetic loci independently. The medA locus, which also affects morphology and pigmentation, may code for a modifier of brlA function. abaA mutants which are blocked at a later stage of development than brlA or medA mutants have low phenol oxidase levels, implying that by this stage of development the activity of the ivoB locus is declining.